KR0171567B1 - Loudspeaker - Google Patents

Abstract

A compound loudspeaker drive unit is disclosed comprising a low frequency unit having an outwardly and forwardly flaring conical diaphragm (21) and a high frequency drive unit (27) located in or adjacent to the neck of the low frequency conical diaphragm such that the acoustic centres of the two units are substantially coincident and, for a cross-over frequency range in which both drive units contribute significant sound output, the directivity of sound radiation from the high frequency unit (27) as acoustically loaded by the low frequency conical diaphragm (21) is substantially the same as that of the low frequency unit. A magnet structure (28,29,30) for the high frequency unit utilises a magnet (29) formed of neodymium iron boron which enables the high frequency unit (27) to be positioned within a drive coil (23,24) for the low frequency diaphragm while providing a required high value of magnetic flux.

Description

Loudspeaker drive unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to loudspeakers, and more particularly to a hybrid loudspeaker drive unit having respective diaphragms for reproducing low and high audible frequencies.

In a conventional loudspeaker system, each loudspeaker driving unit for reproducing an audible frequency band, for example, a woofer unit for reproducing low frequency sound and a tweeter unit for reproducing high frequency sound unit is provided. The voice coil of the loudspeaker drive unit is connected to the output of a power amplifier or other source via a suitable crossover filter circuit that ensures that only an electrical signal representing a suitable band of sound is applied to each loudspeaker voice coil. The characteristics of the crossover filter allow the output of the two loudspeaker drive units to be attenuated in the mid-frequency coarse-over band, which is halfway between the low and high frequency bands, and the output of the low-frequency loudspeaker drive unit decreases as the frequency increases. On the other hand, the output of the high frequency loudspeaker drive unit can be reduced when the frequency is lowered. At the so-called coarseover frequency, the low and high frequency loudspeaker drive units have the same output, but these outputs are reduced compared to their output within their respective frequency bands. The electrical operation of each voice coil is adjusted so that the acoustic output of the loudspeaker drive unit is relatively matched and provides a uniform output over the entire frequency range of the two loudspeaker drive unit combinations. The sound radiated from each drive unit can be said to be radiated from the virtual point sound source of this unit, that is, the sound center. The position of this sound center can vary depending on the design of the specific unit, Can be determined.

When the loudspeaker drive units are provided independently, the virtual point sound sources are physically placed in different positions. Typically the loudspeaker drive units are mounted on a common baffle so that they are in a common plane and at different positions in the vertical direction in the plane of the baffle. If the listener is on a line coincident with the axis of the loudspeaker drive unit and at the same distance from the acoustic center of both drive units, the required output parallelism from both drive units can be obtained. However, if the listener's position is moved from an equidistant position, the distance between the listener and the acoustic center of the two loudspeaker drive units will be different, so that the sound in the intermediate frequency band generated by both loudspeakers will be heard from the two drive units by the time difference. . This time difference between the two sounds heard from the two drive units results in a change in the phase relationship of the sounds heard from the two drive units at the listening position. The sounds from the two drive units are no longer summed together as intended in the crossover band. Thus, the sound level heard will vary with frequency and all sound output of the loudspeaker combination will not be uniform to the listener. This mismatch of sound output makes the sound loud, and in the case of a stereo sound system, the position of the virtual instrument on the stage is not clearly distinguished. This is particularly noticeable in the acoustic frequency region of the mid-phase range, for example, in the region of 3 kHz where the position between driving units is close to the wavelength of sound. At a frequency of 3 kHz, the wavelength is about 4 inches, or 100 cm.

In an attempt to overcome the undesirable effects of sound heard at locations not equidistant from two loudspeaker drive units, it is known to combine high frequency and low frequency loudspeaker drive units into a single complex coaxial structure. This composite coaxial loudspeaker drive unit is generally composed of a magnet structure having a central magnetic pole extending through the voice coil and a conical low frequency vibration plate driven by the voice coil. The high frequency vibration plate is disposed on the rear side of the magnet structure and the sound output from the vibration plate is directed toward the front of the loudspeaker driving unit by a horn structure extending coaxially through the central stimulus of the magnet structure interacting with the low frequency vibration plate. do. Thus, low and high frequency sounds are directed forward from the composite loudspeaker drive unit. In this coaxial form of the loudspeaker structure, no vertical or horizontal offset of the virtual point sound source for low and high frequencies appears. However, while the low frequency vibration plate is arranged in front of the loudspeaker unit, the high frequency vibration plate is arranged in the rear of the loudspeaker unit, and as a result, the relative displacement of the virtual point source sound in the axial direction of the drive unit appears and is output from the high frequency and low frequency vibration plate. Unnecessary time difference appears for the sound to reach the listener.

According to an aspect of the present invention, a hybrid loudspeaker drive unit comprises a first transducer that operates to generate sound in a low frequency region and a second transducer that operates to generate sound in a high frequency region, wherein the low frequency and high frequency regions cross each other. The first transducer has a conical diaphragm that extends outwardly from the neck portion, and the second transducer has a conical shape in the crossover region that coincides with the effective acoustic center of the first and second transducers. The conical diaphragm of the first transducer is the position where both transducers are matched against the full frequency in the crossover region where the transducers have directivity to the acoustic radiation from the second transducer and thus affect the acoustic output of the drive unit. It is arranged at or adjacent to the neck portion of.

According to a second aspect of the present invention, a hybrid loudspeaker drive unit comprises a low frequency moving coil drive unit and a high frequency moving coil drive unit, wherein the high frequency drive unit includes a magnet means for interacting with the moving coil. The magnet means comprises a permanent magnet composed of neodymium-iron-boron or a permanent magnet composed of a material having similar or better magnetic properties.

The hybrid loudspeaker drive unit provides a frusto-conical low frequency diaphragm extending outwardly from the neck portion, a low frequency acoustic coil connected to the neck portion of the diaphragm, and a magnetic flux interacting with the low frequency acoustic coil to electrically operate the voice coil. A low frequency drive unit composed of first magnet means for applying motion to the diaphragm to generate sound in a low frequency region; A high frequency loudspeaker driving unit disposed adjacent to the neck portion of the low frequency vibration plate and composed of a high frequency vibration plate for reapplying a high frequency voice coil; The electrical operation of high-frequency voice coils exerts motion on the high-frequency vibrating plate, including permanent magnets consisting of neodymium-iron-boron or similar materials with better or better magnetic properties and providing magnetic flux to interact with the high-frequency voice coils. And second magnet means for generating sound in the high frequency region overlapping the low frequency region in the crossover band.

The high frequency drive unit is preferably arranged with respect to the low frequency drive unit so that the virtual point sound sources of the two units coincide.

If necessary, an annular baffle member may be provided to allow the surface of the low frequency vibration plate to be continuous toward the high frequency vibration plate.

In the loudspeaker according to the third aspect of the present invention, which is composed of coaxially arranged low frequency and high frequency driving units, the high frequency driving unit is manufactured separately from the low frequency driving unit and fixed to the magnetic pole pieces of the magnet means of the low frequency driving unit. do.

The magnetic pole piece of the low frequency drive unit has a central hole extending through the center, and the high frequency drive unit protrudes therefrom and is coupled to the hole so that a rod of nonmagnetic material can be disposed with respect to the high frequency drive unit. Have

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT An embodiment of the present invention will be described in detail with reference to the accompanying drawings showing a cross-sectional view through an axis of a moving coil type hybrid loudspeaker drive unit.

In the figure, a hybrid loudspeaker drive unit composed of a low frequency and a high frequency transducer having coaxial low frequency and high frequency voice coils has a front annular border 11 connected to the rear annular member 12 by a plurality of ribs 13. It is composed of a chassis 10 in the form of a conical basket. The rear annular member 12 has an annular flange 14 and an annular sheet 15. On the flange 14, the first magnet structure 16 of the low frequency loudspeaker driving unit is mounted. The magnet structure 16 includes, for example, a magnet ring 17 made of barium ferrite, a front annular plate 18 for forming an external magnetic pole, and a member 19 for forming a back plate and an internal magnetic pole 20. It is composed. The front annular plate 18, the magnet ring 17 and the member 19 are fixed together to provide a magnetic path between the external magnetic pole 18 and the inner magnetic pole 20 which is nonmagnetically blocked by the air gap. do. The poles are circular and form an annular air gap between them. The low frequency transducer or loudspeaker drive unit is composed of a truncated cone-shaped diaphragm 21 supported along its front outer edge by a flexible rim 21 mounted on the front rim 11 of the chassis 10. A tubular coil cloth 23 is mounted on the rear edge portion of the diaphragm 21 and is arranged to extend coaxially with an air gap formed in the magnet structure 16. The voice coil 24 is disposed in the coil former such that the coil extends through the air gap. The coil has a sufficient axial length so that the magnetic pole always lies within the length of the voice coil even if the voice coil flows. A spider-shaped suspension member 25 composed of inner and outer rings interconnected by a flexible extension or pleated sheet having annular pleats is applied to the coil former and the coil former during the acoustic vibration of the diaphragm 21. The voice coil is fixed between the coil former 23 and the annular sheet 15 of the chassis 10 so as to maintain concentricity with the magnetic pole of the magnet structure and prevent physical contact with the magnetic pole. The member 19 forming the back plate and the internal magnetic pole has a through hole 26 extending coaxially to install the high frequency drive unit 27.

The high frequency converter or drive unit 27 is composed of a second magnet structure composed of a port 28, a disk magnet 29 and a disk internal magnetic pole 30. The port 28 has a cylindrical outer surface that can be inserted without being in physical contact with the interior of the coilformer 23. The port is formed with a circular demand 31 for accommodating the magnet 29, and an annular piece 32 for forming an external stimulus is formed. One circular magnetic pole surface of the magnet 29 is fixed to be coupled to the bottom wall of the request 31 and the disk-shaped inner magnetic pole 30 is fixed to be coupled to the other circular magnetic pole surface of the magnet to the circular outer peripheral portion of the inner magnetic pole 30 Is arranged coaxially with this annular piece in the annular piece 32 which forms an external magnetic pole. A nonmagnetic air gap extends between the inner and outer poles. The spacer ring 33 is fixed to the front of the port 28. The magnet 29 is preferably composed of a neodymium-iron-boron magnetic material having a very high magnetic field strength obtained in the air gap between magnetic poles, compared to other useful magnetic materials. Therefore, the overall size of the high frequency magnet structure is smaller than that of the prior art in order to obtain the required magnetic flux in the air gap so that the high frequency drive unit can be disposed in the coil former of the low frequency drive unit near the apex of the low frequency vibration plate 21. . However, magnet 29 may be composed of other materials having magnetic properties similar to or better than neodymium-iron-boron. The dome-shaped high frequency vibration plate 34 has an annular corrugated annular support 35, which is fixed to the spacer ring 33 at the outer periphery. In the dome-shaped diaphragm 34, a cylindrical coil former for installing the high frequency voice coil 36 is installed so that the voice coil extends through the air gap between the magnetic poles 30 and 32 of the magnet structure.

A lot of nonmagnetic material 37 for arranging the high frequency unit centered with respect to the low frequency unit, and in particular to ensure that the high frequency unit is coaxial with the low frequency acoustic coil and does not interfere with the movement of the low frequency acoustic coil. Is fixed centered on the back of the port 28 and extends through the aperture 26 of the low frequency magnet structure. The high frequency drive unit is fixed to the magnetic pole 20 of the magnet structure 16 by magnetic force, but the spiral end portion of the rod 37 extending through the through hole of the plate body 39 disposed on the back plate 19 (38) and a nut (40) screwed to the end (38) are mounted on the structure (16). The low frequency voice coil 24 is connected by a flexible conductor 41 extending from the voice coil 24 to the external connector 42. The high frequency voice coil 36 has flexibility extending between the port 30 and the inner stimulus 20 and through an aperture 26 to an outer connector (not shown) as required on the outer wall of the port 30. The connection is made by the conductor 43. In order to extend the conductive wire through the through hole 26, the rod 37 has a diameter smaller than the diameter of the through hole 26 so as to leave an annular space portion in which the conductive wire 43 extends.

Means (not shown) for placing the rod coaxially with the aperture 26 are provided between the pole 20 and the port 28. This means can be configured in the form of a disk secured to the pole 20 and having a central hole of diameter through which the rod 37 can be inserted. There is a requirement in the disc to provide a through hole through which the conductor 43 can pass between the pole 20 and the port 28. The rod 37 may have a circular, hexagonal, or other shaped cross section and the disk may be provided with a circular through hole that matches the cross-sectional shape of the rod.

Instead of using a rod 37 having a weave smaller than the diameter of the through hole 26, if the rod has a hexagonal cross section, the diameter of the rod is such that the rod is placed coaxially with the pole 20 of the low frequency drive unit. It may be sized to be inserted into the through hole 26 in order to. A space portion through which the conductive wire 43 passes is provided between each side of the rod of hexagonal section and the wall of the through hole 26. Instead of using the plate body 39 to fix the high frequency drive unit, a molding may be used. Such moldings may be placed with a boss formed in the molding being inserted into the through hole 26. The molding may also be configured to provide mounting means for mounting such components as the electronic component of the crossover filter and the terminal of the electric drive signal applied to the composite loudspeaker drive unit. Instead of forming an outer helix at the end 38 of the rod 37, a spiral hole may be formed at the end of the rod to spirally screw the screw thereto.

The configuration described above is particularly suitable for the manufacture of a hybrid loudspeaker drive unit in which the high frequency drive unit is centered with respect to the low frequency drive unit before the high frequency drive unit reaches its final placement position on the pole 20. Therefore, the high frequency unit is prevented from contacting the low frequency sound coil during the assembly of the composite loudspeaker drive unit. Furthermore, this configuration makes it possible to easily disassemble the high frequency drive unit from the low frequency drive unit when the unit needs to be repaired without having to demagnetize the magnet assembly. If desired, an annular baffle 44 having a truncated conical front surface is fixed to the front of the high frequency drive unit so that the surface of the low frequency vibration plate 21 is maintained toward the dome type high frequency vibration plate.

In the above-mentioned configuration of the hybrid loudspeaker drive unit, the high frequency drive unit is disposed at or adjacent to the neck of the diaphragm of the low frequency drive unit, so that the virtual point sound source or the acoustic center of the high frequency drive unit is the virtual point sound source of the low frequency drive unit. Or it can be seen that it coincides with the acoustic center. The radiation pattern or directivity of the low frequency drive unit is determined by the shape of the low frequency vibration plate. Since the high frequency driving unit is disposed adjacent to the neck portion of the low frequency vibration plate, the shape of the low frequency vibration plate affects the radiation pattern and directivity of the high frequency unit. Therefore, both frequency drive units have similar radiation patterns or directivity at frequencies at which both drive units deliver significant sound output. Thus, the relative acoustic output from the two drive units sensed by the listener can be listened to unchanged by the listener at a position off the axis of the drive unit.

The conical low frequency vibration plate is shown in the figure in the form of a conical shape with an expanding angle from the neck of the diaphragm towards the outer periphery of the diaphragm. However, the diaphragm may be in the form of a conical shape with a constant angle of expansion. Alternatively, the conical low frequency vibration plate may have the shape of a circular, elliptical or other desired cross section.

The high frequency vibration plate is shown in the form of a dome. These diaphragms can be easily arranged so that their acoustic centers closely match the acoustic centers of low-frequency vibration plates, and their non-directional acoustic radiation is small in size compared to the wavelength in the frequency region where both drive units deliver significant sound output. It is suitable to make the effective orientation can be determined by the low frequency vibration plate. In addition, the high frequency vibration plate may be configured in other forms to provide these characteristics.

Claims (6)

The first fixed to the neck portion of the first conical low-frequency diaphragm 21, the voice coil former 23, and fixed to the neck portion of the conical first diaphragm to generate sound in the low-frequency region. The second coil fixed to the peripheral portion of the high frequency vibration plate disposed adjacent to or adjacent to the net portion of the voice coil 24, the dome-shaped high frequency second diaphragm 34 for generating sound in the high frequency region, and the conical vibrating plate 21. A voice coil 36 and first and second air gaps extending from the first and second voice coils, respectively, and interacting with the first voice coil to form a first magnetic flux and the second magnetic gap in the first air gap. Magnet means (17, 18, 19, 20, 28, 29, 30, 32) for interacting with the voice coil to generate a second magnetic flux in the second air gap, wherein the magnet means comprises a first magnet structure ( 17, 18, 19, 20) and the first magnet structure and A low frequency vibration plate 21 and the high frequency vibration plate 34 including a first permanent magnet 17 generating a first magnetic flux in a first magnetic flux path of an air gap, wherein the low frequency vibration plate 21 and the high frequency vibration plate 34 overlap in a crossover region; It is possible to generate a sound in the high frequency region and the both side vibration plate is capable of sufficient sound output in the crossover region, and the magnet means is the second magnet structure (28, 29, 30, 32) and the second A magnet structure and a second permanent magnet 29 for generating a second magnetic flux in the second magnetic flux path of the second air gap, the second magnet structure 28, 29, 30, 32 is the first magnet Detachable from the structure, the second permanent magnet 29 is composed of a neodymium-iron-boron compound so that the second magnet structure has a neck of the first diaphragm 21 with respect to the required magnetic flux in the second air gap. Voice adjacent to a part It is small enough to be accommodated in the coil former 23 of the coil 24, and the second magnet structure is disposed in the voice coil former 23 adjacent to the neck portion of the first diaphragm. The second diaphragm has an effective acoustic center and the second diaphragm is disposed with respect to the first diaphragm so that the effective acoustic centers of the first and second diaphragms coincide with each other, so that the conical first diaphragm 21 in the crossover region is provided with both side diaphragms. Loudspeaker driving characterized by imparting directivity to the second diaphragm 34 so that the directivity of the first and second diaphragms can be matched at all frequencies in the crossover region which contributes sufficiently to the acoustic output of the drive unit. Unit. The loudspeaker drive unit according to claim 1, wherein the first diaphragm (21) is extended outwardly at an enlargement angle gradually increasing from the net portion to the front periphery of the diaphragm. The neck portion of the first low frequency diaphragm 21 according to claim 1 or 2, wherein the low frequency sound coil which is mounted by the voice coil former 23 installed on the neck portion of the first low frequency diaphragm 21 is conical. Spaced rearward from the second magnet structure (28, 29, 30, 32) is disposed in the voice coil former in the middle of the neck portion of the conical low frequency first diaphragm 21 and the low frequency audio coil 24 Loudspeaker drive unit, characterized in that. The first magnet structure (17, 18, 19, 20) and the first diaphragm 21 constitute a first unit, and the second magnet structure (28, 29, 30, 32). ) And a second diaphragm 27 constitute a second unit separate from the first unit, and the first magnet structure includes a central magnetic pole 20 having a central through hole 26 extending in an axial direction. The second magnet structure 28, 29, 30, 32 is connected to the second magnet structure 28, 29, 30, 32 through the through hole 26 to arrange the second magnet structure with respect to the first magnet structure. Loudspeaker drive unit comprising a rod (37) of nonmagnetic material extending outwardly from the. 5. The loudspeaker drive unit according to claim 4, wherein the second magnet structure (28, 29, 30, 32) is fixed to the front end of the central magnetic pole (20) of the first unit. 5. The loudspeaker according to claim 4, characterized in that the conductor (43) extends between the wall of the central aperture (26) and the rod (37) to allow electrical connection of the second voice coil (36) through the central aperture. Speaker drive unit.